Rapid Discovery and Detection of Haemaphysalis longicornis through the Use of Passive Surveillance and Collaboration: Building a State Tick-Surveillance Network

Fryxell, Rebecca Trout; Vann, Dené N.; Butler, Rebecca; Paulsen, Dave; Chandler, J. G.; Willis, Micah P.; Wyrosdick, Heidi M.; Schaefer, John J.; Gerhold, Richard W.; Grove, Daniel M.; Ivey, Jennie Z.; Thompson, Kevin W.; Applegate, Roger D.; Sweaney, Joy; Daniels, Sterling; Beaty, Samantha; Balthaser, Douglas; Freye, James D.; Mertins, James W.; Bonilla, Denise L.; Lahmers, Kevin K.

doi:10.3390/ijerph18157980

Cited by 17 publications

(23 citation statements)

References 47 publications

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“…Ectoparasite collection was typically conducted when the citizen scientists interacted with the animal as part of their clientele (e.g., during a veterinary checkup or bringing stray animals into a shelter). To assist with vector collections, citizen scientists were either sent collection kits and materials [ 13 , 14 , 15 , 16 , 17 ] or exclusively given instructions via email, print material, or project website [ 18 , 19 , 20 ] on procedures to collect, preserve, and send specimens to researchers. When considering whether to send collection kits to citizen scientists, researchers should consider the cost to mail and receive the kits, whether special chemicals for specimen or pathogen preservation are required, and how differences in preservation or submission could affect the specimen or pathogen status.…”

Section: Professional Companion Animal Accessmentioning

confidence: 99%

“…This is especially useful when considering invasive vectors that are introduced into new geographic regions. For example, Duncan et al [ 13 ] and Trout-Fryxell et al [ 15 ] relied on communication and action of this citizen scientist group to detect and track the spread of the invasive Asian long-horned tick ( Hamephysalis longicornis ), which was first reported in the U.S. in 2017 [ 39 ]. A similar program was also conducted in Michigan with I. scapularis and the causative agent of Lyme disease Borrelia burgdorferi , where citizen scientists, including those with professional access to companion animals, were asked to submit samples to develop a comprehensive distribution of the tick and bacterium throughout the state [ 40 ].…”

Section: Professional Companion Animal Accessmentioning

confidence: 99%

“…Working with this stakeholder group, researchers utilized a variety of methods to passively sample ectoparasites, including using collection kits that were available through different avenues (available for pickup/drop off at researcher/Extension offices or sent to citizen scientists), submitting specimens to a research laboratory or institution, and submitting photos to a website or mobile device application. Unlike those who had occupations working with animals, only two studies that targeted animal owners utilized pre-made collection kits [ 15 , 24 ]. Instead, the majority of studies that involved animal owners advertised their studies online using a dedicated project website and/or outreach to recruit citizen scientists [ 18 , 37 , 46 , 47 , 48 , 49 , 50 , 51 ].…”

Section: Personal Companion Animal Accessmentioning

confidence: 99%

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All for One Health and One Health for All: Considerations for Successful Citizen Science Projects Conducting Vector Surveillance from Animal Hosts

Poh

Evans

Skvarla

et al. 2022

Insects

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Many vector-borne diseases that affect humans are zoonotic, often involving some animal host amplifying the pathogen and infecting an arthropod vector, followed by pathogen spillover into the human population via the bite of the infected vector. As urbanization, globalization, travel, and trade continue to increase, so does the risk posed by vector-borne diseases and spillover events. With the introduction of new vectors and potential pathogens as well as range expansions of native vectors, it is vital to conduct vector and vector-borne disease surveillance. Traditional surveillance methods can be time-consuming and labor-intensive, especially when surveillance involves sampling from animals. In order to monitor for potential vector-borne disease threats, researchers have turned to the public to help with data collection. To address vector-borne disease and animal conservation needs, we conducted a literature review of studies from the United States and Canada utilizing citizen science efforts to collect arthropods of public health and veterinary interest from animals. We identified common stakeholder groups, the types of surveillance that are common with each group, and the literature gaps on understudied vectors and populations. From this review, we synthesized considerations for future research projects involving citizen scientist collection of arthropods that affect humans and animals.

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Section: Professional Companion Animal Accessmentioning

confidence: 99%

Section: Professional Companion Animal Accessmentioning

confidence: 99%

Section: Personal Companion Animal Accessmentioning

confidence: 99%

See 1 more Smart Citation

All for One Health and One Health for All: Considerations for Successful Citizen Science Projects Conducting Vector Surveillance from Animal Hosts

Poh

Evans

Skvarla

et al. 2022

Insects

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“…Passive surveillance systems, in which tick specimens found on humans and animals are submitted to researchers by members of the public or veterinary and medical practices, have contributed significantly to knowledge of tick distribution, seasonal activity, host associations, and pathogen infection prevalence in North America, and can act as early warning systems for the introduction, establishment, and expansion of species of public health or veterinary concern [ 19 , 24 , 28 , 29 , 30 , 31 , 32 , 33 , 34 , 35 , 36 , 37 , 38 , 39 , 40 , 41 , 42 , 43 , 44 , 45 , 46 , 47 , 48 , 49 , 50 , 51 ]. Results from passive tick surveillance have been demonstrated to correlate well with the distribution of tick-borne diseases [ 7 , 29 , 45 , 52 , 53 , 54 ] and tick abundance from active surveillance [ 55 ].…”

Section: Introductionmentioning

confidence: 99%

Monitoring Trends in Distribution and Seasonality of Medically Important Ticks in North America Using Online Crowdsourced Records from iNaturalist

Cull

2022

Insects

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Recent increases in the incidence and geographic range of tick-borne diseases in North America are linked to the range expansion of medically important tick species, including Ixodes scapularis, Amblyomma americanum, and Amblyomma maculatum. Passive tick surveillance programs have been highly successful in collecting information on tick distribution, seasonality, host-biting activity, and pathogen infection prevalence. These have demonstrated the power of citizen or community science participation to collect country-wide, epidemiologically relevant data in a resource-efficient manner. This study examined tick observations from the online image-based biological recording platform iNaturalist to evaluate its use as an effective tool for monitoring the distributions of A. americanum, A. maculatum, I. scapularis, and Dermacentor in the United States and Canada. The distribution and seasonality of iNaturalist tick observations were found to accurately represent those of the studied species. County-level iNaturalist tick occurrence data showed good agreement with other data sources in documented areas of I. scapularis and A. americanum establishment, and highlighted numerous previously unreported counties with iNaturalist observations of these species. This study supports the use of iNaturalist data as a highly cost-effective passive tick surveillance method that can complement existing surveillance strategies to update tick distributions and identify new areas of tick establishment.

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“…Currently published surveillance studies for H. longicornis in the U.S. are limited geographically and as a result are unlikely to capture the potential wildlife host range utilized by H. longicornis [35,40,41,[43][44][45]. In addition, habitat suitability models primarily focusing on climatic and geographic variables to predict the potential range of H. longicornis have been reported, but they were built around limited datasets of H. longicornis occurrences (rather than established population data) and therefore may not accurately depict all suitable habitats in the U.S. [46][47][48].…”

mentioning

confidence: 99%

The wild life of ticks: using passive surveillance to determine the distribution and wildlife host range of ticks and the exoticHaemaphysalis longicornis, 2010-2021

Thompson

White

Doub

et al. 2022

Preprint

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BackgroundWe conducted a large-scale, passive regional survey of ticks associated with wildlife of the eastern U.S. Our primary goals were to better assess the current geographic distribution of exotic H. longicornis and to identify potential wild mammalian and avian host species. However, this large-scale survey also provided valuable information regarding the distribution and host associations for many other important tick species that utilize wildlife as hosts.MethodsTicks were opportunistically collected by cooperating state and federal wildlife agencies. All ticks were placed in the supplied vials and host information was recorded, including host species, age, sex, examination date, location (at least county and state), and estimated tick burden were recorded. All ticks were identified to species using morphology, suspect H. longicornis were confirmed through molecular techniques.ResultsIn total, 1,940 hosts were examined from across 369 counties from 23 states in the eastern U.S. From these submissions, 20,626 ticks were collected and identified belonging to 11 different species. Our passive surveillance efforts detected exotic H. longicornis from nine host species from eight states. Notably, some of the earliest detections of H. longicornis in the U.S. were collected from wildlife through this passive surveillance network. In addition, numerous new county reports were generated for Amblyomma americanum, A. maculatum, Dermacentor albipictus, D. variabilis, and Ixodes scapularis.ConclusionsThis study provided data on ticks collected from animals from 23 different states in the eastern U.S. between 2010 – 2021 with the primary goal of better characterizing the distribution and host-associations of the exotic tick H. longicornis; however new distribution data on tick species of veterinary or medical importance was also obtained. Collectively, our passive surveillance has detected numerous new county reports for H. longicornis as well as I. scapularis. Our study utilizing passive wildlife surveillance for ticks across the eastern U.S. is an effective method for surveying a diversity of wildlife host species allowing us to better collect widespread data on current tick distributions relevant to human and animal health.

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Rapid Discovery and Detection of Haemaphysalis longicornis through the Use of Passive Surveillance and Collaboration: Building a State Tick-Surveillance Network

Cited by 17 publications

References 47 publications

All for One Health and One Health for All: Considerations for Successful Citizen Science Projects Conducting Vector Surveillance from Animal Hosts

All for One Health and One Health for All: Considerations for Successful Citizen Science Projects Conducting Vector Surveillance from Animal Hosts

Monitoring Trends in Distribution and Seasonality of Medically Important Ticks in North America Using Online Crowdsourced Records from iNaturalist

The wild life of ticks: using passive surveillance to determine the distribution and wildlife host range of ticks and the exoticHaemaphysalis longicornis, 2010-2021

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